The design of DNA self-assembled computing circuitry

Author

Dwyer, Chris ; Vicci, Leandra ; Poulton, John ; Erie, Dorothy ; Superfine, Richard ; Washburn, Sean ; Taylor, Russell M.

Author_Institution

Dept. of Electr. & Comput. Eng., Duke Univ., Durham, NC, USA

Volume

12

Issue

11

fYear

2004

Firstpage

1214

Lastpage

1220

Abstract

We present a design methodology for a nanoscale self-assembling fabrication process that uses the specificity of DNA hybridization to guide the formation of electrical circuitry. Custom design software allows us to specify the function of a structure in a way similar to that used by VLSI circuit designers. In an analogous manner to generating masks for a photolithographic process, our software generates an assembly procedure including DNA sequence allocation. We have found that the number of unique DNA sequences needed to assemble a structure scales with its surface area. Using a simple face-serial assembly order we can specify an unambiguous assembly sequence for a structure of any size with only 15 unique DNA sequences.

Keywords

DNA; computer architecture; logic gates; masks; nanoelectronics; parallel processing; photolithography; self-assembly; DNA hybridization; DNA sequence allocation; VLSI circuit design; computing circuitry; custom design software; electrical circuitry; logic gates; masks; nanoscale self assembling fabrication process; photolithographic process; Assembly; Circuits; Computer architecture; DNA computing; Metallization; Nanowires; Parallel processing; Self-assembly; Sequences; Space technology; Associative memories; DNA self-assembly; computer architecture; nanoelectronics; parallel processing;

fLanguage

English

Journal_Title

Very Large Scale Integration (VLSI) Systems, IEEE Transactions on

Publisher

ieee

ISSN

1063-8210

Type

jour

DOI

10.1109/TVLSI.2004.836322

Filename

1350794